Method and system for effecting changes in pigmented tissue

ABSTRACT

Methods and systems are described for a rapid and sustainable change in the pigment melanin content of melanocytes of the iris stroma, thereby to change the color of the eye. Also described are nanoparticle compositions for lightening the pigmented tissues or treating a pigmented tissue related disease.

This application claims priority of U.S. Provisional Application Nos. 61/343,558, filed Apr. 30, 2010, 61/271,961, filed Jul. 29, 2009, and 61/271,498, filed Jul. 22, 2009, the contents of each of which are hereby incorporated by reference.

Throughout this application, certain publications are referenced. Full citations for these publications may be found immediately preceding the claims. The disclosures of these publications in their entireties are hereby incorporated by reference into this application in order to describe more fully the state-of-the art to which this invention relates.

BACKGROUND OF THE INVENTION

With respect to cosmetic affects, it is known that large populations of people desire to enhance or to change the color of their eyes, skin or hair. As an example, there exists a large market for providing a change or an enhancement of the color of the eyes. Intra-ocular implants have been provided heretofore for the purpose of enhancing or changing the color of the eyes. The markets for hair color-altering compositions and topical applications for bleaching skin discolorations are also huge markets.

Cosmetic treatment of skin and hair color has heretofore been problematic. Multiple topical applications of sometimes toxic compositions have been required to achieve the desired cosmetic effect, such as a change in color.

In addition, various barriers exist that have heretofore slowed the penetration of active ingredients administered by the ocular route. Both precorneal and corneal factors considerably restrict ocular penetration. The low bioavailability of classical ophthalmic dosage forms can be improved by several approaches, particularly by increasing the time the active ingredients remain in contact with the eye tissues.

Many approaches have been tried, including color contact lenses, implants and laser surgery, to change the color of the eye, none with good results. There is demand for an agent that would safely and effectively change the color of the iris.

With respect to the eyes, a problem exists in that large populations of people are being treated with glaucoma medications derived from prostaglandin analogs. Many such medications cause the conjunctiva to become darker or darkly spotted and the iris of the eye to become darker. These situations often result in unsightly and embarrassing appearance of the eyes. Many people are beginning to experience this problem. This is due at least in part to the aging population in which the prevalence of glaucoma is pronounced. Older people are susceptible to glaucoma and have demonstrated unhappiness with the darkening eye color effect of the glaucoma medications, usually administered in the form of eye drops. There is a great desire in the general public and as a result a large market for a mechanism to alter the color of the eye from brown to hazel, green, and blue.

There exists a need for a quickly penetrating topical eye medication by which eye color in healthy people can be changed safely or eye discoloration that resulted from the necessary use of existing glaucoma medications in some people can be reversed. In addition, a medication is needed that overcomes precorneal and corneal factors inhibiting penetration so as to affect the pigmentation of the conjunctiva and iris of the eye by reducing the coloration thereof. There also exists a need for a delivery system for cosmetic or therapeutic chemicals or medications that targets the melanin in pigmented tissue in the eyes, the skin, the follicle roots of the hair or the base tissue of the nails so as to be capable of effecting cosmetic changes, for example in the color of the iris, the skin and of the hair, or targeting and delivering treatments for diseases that occur in pigmented tissue without adversely affecting healthy tissue.

SUMMARY OF THE INVENTION

The subject application describes a method of lightening the color of the iris of a human subject. In this method, a composition of a tyrosinase inhibitor is administered to the iris of a human subject in an amount effective to lighten the color of the iris. Such composition can also contain at least one melanogenesis inhibitor.

The subject application also describes a method of introducing pigments to the iris of a human subject. In this method, at least one melanogenesis promoter is administered to the iris of a human subject in an amount effective to introduce pigments to the iris. The iris of the human subject becomes darker after such treatment.

The subject application further describes another method of introducing pigments to the iris of a human subject. In this method, a biological dye is administered to the iris of a human subject in an amount effective to introduce pigments to the iris. The iris of the human subject changes color and/or glows after such treatment.

The subject application yet further describes a nanoparticle composition for lightening pigmented tissues. This nanoparticle composition contains a targeting agent of melanocytes chemically bound to a pharmaceutical composition comprising a tyrosinase inhibitor. Such pharmaceutical composition can also contain at least one melanogenesis inhibitor.

The subject application yet further describes a method for lightening pigmented tissuess of a human subject. In this method, the nanoparticle composition described herein is administered to the human subject so as to lighten the pigmented tissues.

The subject application yet further describes another nanoparticle composition for treating a pigmented tissue related disease. This nanoparticle composition contains a targeting agent of melanocytes chemically bound to a pharmaceutical composition containing an active agent for the disease.

The subject application yet further describes a method for treating a pigmented tissue related disease. In this method, the nanoparticle composition described herein is administered to a human subject afflicted with a pigmented tissue related disease so as to treat the disease.

In the methods described herein, the targeting agent binds to cells of the pigmented tissues to permit the release of the pharmaceutical composition directly into the cells of the pigmented tissue without affecting non-pigmented cells.

The subject application yet further describes a method of depigmenting the iris melanocytes to lighten the color of the iris. This method includes the use of one or more of the following steps:

Blocking the sympathetic and parasympathetic nerve supply to the melanocytes using botulinum toxin and memantine;

Preventing tyrosine conversion to melanin by one of available tyrosinase inhibitors;

Preventing Melanocyte-stimulating hormone activation (MSH) by using 2,5-Dimethyl-4-hydroxy-3(2H)-furanone (DMHF);

Inhibiting the COX-2 enzyme using NSAIDS;

Preventing melanogenesis by using a cholinergic agonist;

Blocking Alpha 1-adrenergic receptors by using antagonist chemicals.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1. Background biology of the eye I

FIG. 2. Background biology of the eye II

FIG. 3. Scheme of neuromuscular synaptic junction

FIG. 4. Snap receptors (SNARE) complex and Synapatosomal associated protein (SNAP)

FIG. 5. Target molecules of botulinum (BoNT) and tetanus (TeNT) toxins inside the axon terminal

FIG. 6. Diagram of melanogenesis process

FIG. 7. Melanin formation scheme

FIG. 8. Extracellular influence

FIG. 9. Intracellular pathway from nucleus to melanosomes

FIG. 10. Intracellular pathway from cell membrane to the nucleus

FIG. 11. Schematic of aqueous flow

FIG. 12. The destiny of nanoparticles in the eye

DETAILED DESCRIPTION OF THE INVENTION

Because eye color is caused by melanin produced by iridial melanocytes, similar strategies to those currently being used to inhibit melanogenesis in the skin may be of benefit, such as tyrosinase inhibition¹¹¹. There already exist many skin lightening treatments, however there are major differences between the melanocytes of the iris and melanocytes of the skin, and as such the existing skin treatments do not apply to the eye. Table 1 below provides a list of the major differences between the melanocytes of the iris and melanocytes of the skin. As a result, the depigmenting chemicals (bleaching agents) of the skin may not work directly on the iris.

There is an interesting naturally occurring change in the color of the eye in Homer's Syndrome³⁻⁵, where over a long period of time the color of the iris turns from brown to blue. This is caused by the blockage of the sympathetic nerve impulses to the iris pigment cells (melanocytes) due to many different reasons, such as a tumor or injury. This suggests that stimulation of melanocytes by nerves may also be important for melanogenesis and that inhibition of sympathetic signalling to melanocytes may be effective for causing decreased iridial melanogenesis.

The melanocytes of the iris have direct synaptic attachment with autonomic nerve endings.^(1,2) The influence of sympathetic neural stimulation and melanogenesis^(3,4) and the color of the iris is a known fact as seen in Homer's syndrome.^(3,5) Also, blocking the biosynthesis of melanin through the use of enzymes and bleaching agents may accentuate the process of depigmentation.

TABLE 1 The fundamental differences between iris and skin relating to the color Iris Skin 1 No Epithelium on the surface Epithelium on the surface 2 Basement membrane behind the stroma BM under basal layer 3 Mesodermal in origin Surface ectoderm in origin 4 Made of Connective tissue & fibrocytes Made of Basal layer and keratinocytes 5 Abundant blood vessels and capillaries No blood vessel or capillaries in the epithelium 6 Pigment in melanocytes only Pigment in melanocytes and keratinocytes 7 Melanocytes scattered in the stroma Melanocytes only in Basal layer 8 Melanin majority “pigment deposits” Melanin majority melanosomes 9 Melanin production minimal (stable) Melanin production constant (very active) 10 Access barriers (cornea & aqueous) Access barriers (stratum corneum & spinosum) 11 Access needs transport system Access through direct contact 12 Melanin production minimal or no Melanin production very sensitive to UV reaction to UV light exposure light exposure 13 Minimal tyrosinase activity Tyrosinase very active 14 Direct innervations to melanocytes Minimal nerve connection to melanocytes 15 Melanogenesis is mostly influenced by Melanogenesis minimal influence by autonomic neural stimulation autonomic nervous system stimulation 16 Melanocytes do not donate or transfer Melanocytes constantly donate and transfer Melanin to the other cells melanin to Keratinocytes 17 Amount of pigment in iris pigment Amount of pigment in skin epithelium is, epithelium has nothing to do with the directly related; the color of the skin color of the eye 18 Variation in colors not limited to the Color variation directly related to amount Melanin alone (Diffraction, light of melanin in skin absorption, Interference . . . ). 19 Pigment in epithelium and stroma Pigment in basal layer and keratinocytes 20 COX-2 is endogenous in iris melanocytes COX-2 is activated by UV exposure or inflammation 21 No response to α-MSH α-MSH causes increased proliferation and melanogenesis 22 MC1R not expressed MC1R regulates melanin synthesis

Due to the fact that melanogenesis is not a linear process, but a cascade of multiple interactive chemical processes, one can intervene at any of multiple steps along the melanogenesis cascade individually, or in combination to reach the desired goal of altering melanin production. By blocking one or more of these steps, and/or by destroying the existing melanin, the bleaching effect can be achieved. For example, the melanocytes of the iris have direct synaptic attachment with autonomic nerve endings^(1,2). The influence of sympathetic neural stimulation and melanogenesis^(3,4) and the color of the iris is a known fact as seen in Horner's syndrome^(3,5). Therefore, as one of the several factors described below, blocking the neural stimulation to iridial melanocytes in isolation or in combination with blocking the biosynthesis of melanin in iridial melanocytes through the use of enzymes and bleaching agents may accentuate the process of depigmentation.

Melanogenesis is initiated with the first step of tyrosine oxidation to dopaquinone catalyzed by tyrosinase. This first step is the rate-limiting step in melanin synthesis because the remainder of the reaction sequence can proceed spontaneously.⁷¹ The Mequinol (4-hydroxyanisole) subsequent dopaquinone is converted to dopa and dopachrome through auto-oxidation. Dopa is also the substrate of tyrosinase and oxidized to dopaquinone again by the enzyme. Finally, eumelanin are formed through a series of oxidation reactions from dihydroxyindole (DHI) and dihydroxyindole-2-carboxylic acid (DHICA), which are the reaction products from dopachrome.

In one example, a method for achieving the hypopigmentation of the iris, may include one or more of the following steps involving medicinal interventions with small molecules:

1. Block the stimulatory nervous input to the melanocytes using drugs such as, but not limited to, botulinum toxin and memantine.^(19,20)

Botulinum toxin can be used to block the synaptic neurotransmitters to prevent melanogenesis by melanocytes, as observed in Horner's Syndrome^(3,4,25). Although many medical uses for botulinum toxin have been documented^(19,20) and patented^(23,24), the only reference to its cosmetic use in the iris teaches away from such use due to potential side effects on the iridial musculature^(28,29). However, botulinum toxin has been used in the eye for the treatment of strabismus for decades³⁸, and also retrobulbar injection was used to treat nystagmus³⁹ without much adverse effect. Accordingly, the use of drug-containing, targeted nanoparticles described herein could minimize the exposure of neighbouring tissues and help prevent complications. This represents a novel use for the botulinum toxin for cosmetic use of pigment alteration in the iridal melanocytes.²⁶

Alternatively, NMDA and AMPA glutamate receptor antagonists such as memantine have been shown to be effective in human cells to block nerve stimulation of melanocytes and therefore decrease pigment production and may also be useful for depigmentation³³

2. Stop tyrosine conversion to melanin by one of many available tyrosinase inhibitors such as hydroquinone²¹, arbutin³⁰, hydroxystibene compounds like resveratrol³¹, or zinc alpha-2-glycoprotein.¹²

The activity of tyrosinase in the stroma of the iris is very limited (90% of activity in iris is in pigment epithelium behind the stroma)^(4,25). Using tyrosinase inhibitors could work alone or in conjunction with other mechanisms of depigmentation to achieve optimal results. Although U.S. Patent Application Publication No. 2000/6359001 (Pharmacia) teaches the use of tyrosinase inhibitors in combination with prostaglandin analogs in order to offset iatrogenic or disease-induced hyperpigmentation in patients being treated for glaucoma, there is no mention of cosmetic use in healthy individuals.

“Hydroquinone, which is a hydroxyphenolic chemical, has been the gold standard for treatment of hyperpigmentation for over 50 years. It acts by inhibiting the enzyme tyrosinase, thereby reducing the conversion of DOPA to melanin. Some of the other possible mechanisms of action are the destruction of melanocytes, degradation of melanosomes, and the inhibition of the synthesis of DNA and RNA.”²¹

3. Stop Melanocyte-stimulating hormone (MSH) activation by using DMHF (2,5-Dimethyl-4-hydroxy-3(2H)-furanone).¹⁴

MSH inhibitors and bleaching agents, when used in combination with the other methods described here, could intensify the bleaching effect and help to achieve the goal of lightening the color of the eye in a shorter span of time.

“Data suggest that DMHF inhibits the downstream step of cAMP production induced by α-MSH, consequently inhibiting melanogenesis. This suggestion was further confirmed by the fact that the increased production levels of microphthalmia-associated transcription factor, tyrosinase and tyrosinase-related protein-1 induced by α-MSH were all reduced by DMHF in B16 melanoma cells. Conclusions: Our study shows that DMHF inhibits α-MSH-induced melanogenesis by suppressing CREB phosphorylation, which is induced by protein kinase A, and suggests that DMHF may be an effective inhibitor of hyperpigmentation.”¹⁴

4. Inhibit the COX-2 enzyme using NSAIDs, such as bromfenac, Celecoxib, a COX-2 inhibitor, has been shown to inhibit the increase of melanin.⁴⁶

The majority of COX activity of the iris stroma has been shown to be of the COX-2 version¹⁰. Although COX-2 activity is known to be present in the iris and ciliary body, it has not been realized heretofore that blocking the COX-2 activity by using an NSAID such as bromfenac would create yet another barrier to melanogenesis.

“Little is known about the distribution of COX-1 and COX-2 in animals. We investigated this in the iris and ciliary body of the normal rabbit eye. The presence of COX-1 and COX-2 in freshly excised iris and ciliary body tissue from adult New Zealand White albino rabbits was demonstrated by real-time RT-PCR and Western blot analysis. The localization of both isoforms and of the neuron-specific protein gene product 9.5 was determined by indirect immunofluorescence. Both enzymes are expressed in the iris and the ciliary body.”²⁷

5. Stop melanogenesis by using a cholinergic agonist. This technique may be especially powerful in combination with neurotoxins from (1), as it could alleviate potential pupillary dilation as a side effect of botulinum administration, for example, but can be reversed by Pilocarpine.

The influence of autonomic neurotransmitters on the uveal melanocytes has been studied and it has been shown that muscarine, a cholinergic agonist, inhibits the growth and melanogenesis in medium.¹ An example of a muscarinic agonist that can be used to interfere with melanogenesis is Pilocarpine, which has been used for many years to treat glaucoma. “Epinephrine, isoproterenol, salbutamol and metaproterenol (adrenergic agonists that can activate β₂-adrenoceptors) substantially stimulated growth and melanogenesis of cultured uveal melanocytes in cAMP-deleted medium. Methoxamine, clonidine, prenalterol and D-7114 (adrenergic agonists that do not activate β₂-adrenoceptors) showed no effect under similar experimental conditions. Muscarine (a cholinergic agonist) inhibited the growth and melanogenesis of uveal melanocytes in complete medium. It indicates that adrenergic agents (β₂-adrenoceptor agonists) stimulate growth and melanogenesis in uveal melanocytes, while cholinergic agonist has an inhibitory effect.”¹

6. Additional small molecule agents that decrease tyrosinase activity in iridial melanocytes whose mechanism of action is upstream of tyrosinase synthesis, such as Haginin A, can be useful in achieving depigmentation.

“Haginin A is an effective inhibitor of hyperpigmentation caused by UV irradiation or by pigmented skin disorders through downregulation via ERK and Akt/PKB activation, MITF, and also by the subsequent downregulation of tyrosinase and TRP-1 production.”³²

7. Another approach to decrease melanogenesis is to prevent pH neutralization or promote pH acidification of melanosomes. This could be achieved by blockage of the activity of the P protein, recently shown to be essential for melanosomal pH neutralization.

“(i) near neutral melanosomal pH is optimal for human tyrosinase activity and melanogenesis; (ii) melanin production in Caucasian melanocytes is suppressed by low melanosomal pH; (iii) the ratio of eumelanin/phaeomelanin production and maturation rate of melanosomes can be regulated by melanosomal pH. We conclude that melanosomal pH is an essential factor which regulates multiple stages of melanin production. Furthermore, since we have recently identified that pink locus product (P protein) mediates neutralization of melanosomal pH, we propose that P protein is a key control point for skin pigmentation.”^(33,34)

8. Amyloid formation in early melanocyes has been shown to be necessary for proper melanogenesis. One example of hypopigmentation subsequent to disruption of normal melanocytic amyloid formation is pmel17 blockage, which results in severe hypopigmentation. As such, phorbol ester or a calmodulin inhibitor may be used to induce Pmel17 shedding.⁶⁵

“Melanocytes synthesize and store melanin within tissue-specific organelles, the melanosomes. Melanin deposition takes place along fibrils found within these organelles and fibril formation is known to depend on trafficking of the membrane glycoprotein Silver/Pmel17. However, correctly targeted, full-length Silver/Pmel17 cannot form fibers. Proteolytic processing in endosomal compartments and the generation of a lumenal Malpha fragment that is incorporated into amyloid-like structures is also essential. Dominant White (DWhite), a mutant form of Silver/Pmel17 first described in chicken, causes disorganized fibers and severe hypopigmentation due to melanocyte death.”³⁵

9. Misdirection of tyrosinase to lysosomes to accelerate its degradation. Inulavosin, a melanogenesis inhibitor, misguides tyrosinase from going to melanosomes to going to lysosomes, where the tyrosinase is destroyed.

“Inulavosin, a melanogenesis inhibitor isolated from Inula nervosa (Composite), reduced the melanin content without affecting either the enzymatic activities or the transcription of tyrosinase or Tyrp1 in B16 melanoma cells. [ . . . ] inulavosin inhibits melanogenesis as a result of mistargeting of tyrosinase to lysosomes.”³⁷

In addition to the methods outlined above in this application, combinatorial approaches with other effective strategies may be desired in parallel or in series for enhanced timing or strength of effect. For example, molecular biological strategies to silence or decrease specific genetic targets involved in the melanin biosynthetic pathway and/or signalling components that stimulate it could be used with any of the strategies listed above. One example would involve use of inhibitory DNA or RNA agents such as siRNAs, as taught in U.S. Patent Application Publication No. 2008/0119433 A1, in combination with agents described in this application, such as botulinum toxin.

10. Targeting of iridial melanocytes. Furthermore, it may be necessary to target the melanocytes specifically, as off-target drug effects may be detrimental. There have been many instances of nanoparticle Drug Delivery Systems (DDS) that transport toxic medications safely to targeted tissue without affecting the surrounding tissue. Examples include a TB drug delivery system¹⁷, cancer treatment¹⁶, and fungal infections²².

In multidirectional approaches to decrease iris pigmentation, in addition to inhibition of tyrosinase catalytic activity, other approaches to decrease iris pigmentation include denervation of melanocytes, inhibition of tyrosinase mRNA transcription, aberration of tyrosinase glycosylation and maturation, acceleration of tyrosinase degradation, interference with melanosome PH, maturation and pigment accumulation, and inhibition of inflammation-induced melanogenic response.

In an embodiment, the emphasis is on using a multiple drug approach together with using Botulinum toxin for changing the color of normally brown eyes to lighter colors. In this embodiment, depigmentation of the iris and as a result a change to the color of the eye is achieved by simultaneous and multiple approaches to stop melanogenesis in the melanocytes in the iris stroma. This includes denervation of the melanocytes by botulinum toxin and stopping the melanogenesis by multiple chemicals that interfere with biosynthesis of the melanin, and muscarine effect that has been shown to inhibit growth and melanogenesis in melanocytes in vitro¹. It has not been known heretofore to use botulinum toxin for altering the color of the eye. Such a technique would result in a rapid and sustainable reduction in melanin content of the iris stroma and thereby a lightening of the color of the eye.

In an example, a method for achieving the bleaching and/or coloring of the iris, may include administering one or more of the following agents to the eyes of a human subject:

-   1. Tyrosinase inhibitor -   2. Glutamate receptor blocker (Memantine)(CAS) -   3. α-adrenergic blocker (Thymoxamine)(CAS) -   4. Cox inhibitor (Bromfenac) -   5. Cholinergic agonist (Pilocarpine)(CAO) -   6. Downregulation of mitf, tyr & Trp1 (Haginin A)(CAD) -   7. Acidification of melanosomes (H89) -   8. Opioid receptor antagonist (Naloxone) -   9. Pmel17 blocker (Calmodulin inhibitors) -   10. Fibroblast growth factor inhibitor -   11. siRNA gene silencing

The following is a list of tyrosinase inhibitors which can be used for the method for achieving the bleaching and/or coloring of the iris described above.

-   1. Kojic acid, the most intensively studied inhibitor of tyrosinase,     is a fungal metabolite currently used as a cosmetic skin-whitening     agent and as a food additive for preventing enzymatic browning⁹¹.     Other slow-binding inhibitors of tyrosinase are the very potent     inhibitor tropolone⁹³ and the substrate analog L-mimosine⁹⁴. -   2. New Inhibitors of Tyrosinase are classified into five major     classes, including polyphenols, benzaldehyde and benzoate     derivatives, long-chain lipids and steroids, other natural or     synthetic inhibitors, and irreversible inactivators based on either     the chemical structures or the inhibitory mechanism. -   3. Polyphenols represent a diverse group of compounds containing     multiple phenolic functionalities and are widely distributed in     nature. Polyphenols are also the largest groups in tyrosinase     inhibitors until now.

Flavonoids are among the most numerous and best-studied polyphenols, that is, benzo-□-pyrone derivatives consisting of phenolic and pyrene rings. Widely distributed in the leaves, seeds, bark, and flowers of plants, more than 4,000 flavonoids have been identified to date. Flavonoids may be subdivided into seven major groups, including: flavones, flavonols, flavanones, flavanols, isoflavonoids, chalcones, and catechin. In addition to flavonoids, other polyphenols, which were also identified as tyrosinase inhibitors, contain stilbenes and coumarin derivatives.

Flavonols: quercetin (5,7,3′,4′-tetrahydroxyflavonol)¹⁰⁰, myricetin (5,7,3′,4′,5′-pentahydroxy-flavonol), kaempferol (5,7,4′-trihydroxyflavonol)¹⁰⁰. galangin (5,7-dihydroxyflavonol), morin, buddlenoid A, buddlenoid B⁹⁸⁻⁹⁹ 6-hydroxykaempferol.¹⁰¹

Flavanones: Norartocarpetin: R═OH (Competitive; RAb, 10.4F)¹⁰⁵, Artocarpetin: R═OCH3 (RAb<0.1F)⁹⁹, Streppogenin (Competitive; RAb, 13.6F)¹⁰⁷

Flavanols: Dihydromorin(RAb, 0.5F)⁹⁹, Taxifolin (RAb,1.0F;ref.46) OOOHOHOOHR2R3R1OOHOOOHOMeOH

Isoflavans: Glabridine(Non-competitive; RAb, 15.2F)¹¹⁷, GlyasperinC (RAb, 27.7F),¹¹⁷ OOHOHOHOH

Isoflavones: Calycosin(RAb, 1.3F)¹²³, 6-Hydroxydaidzein: R1=R3=H, R2=OH (Competitive; RAb, 6.0F)¹¹⁹, 8-Hydroxydaidzein: R1=R2=H, R3=OH (Suicide substrate)¹²⁰, 8-Hydroxygenistein: R1=R3=OH, R2=H(Suicide substrate)¹²⁰, Isoflav-3-enOOHOHOOHR, HagininA (Non-competitive; RAb, 10.1F)¹²¹

Chalcones: 2,4,2′,4′-Tetrahydroxychalcone: R═H (Competitive; RAb, 2.5F)¹³², 2,4,6,2′,4′-Pentahydroxychalcone: R═OH (Competitive; RAb, 12.0F)¹³², ROHOOHOHOH

Prenylated Chalcones: OHOOHMeOLicochalconeA (Competitive; RAb, 5.4F)¹²⁴, OHOOHOHOHTMBC (Competitive; RAb, 26.1F)¹²⁷, OHOOHOHOMeOHOHOOHOHOMeOHOHKuraridin (RAb, 34.1F)¹²⁵, Kuraridinol (Non-competitive; RAb, 18.4F)¹²⁶

N-Benzylbenzamides: NHOR1R2R3R4R5OH3,5,2′,4′-Tetrahydroxyl derivatives: R1=R3=H, R2=R4=R5=OH (RAa, 7.4F)¹³³, 2,4,2′,4′-Tetrahydroxyl derivatives: R1=R3=R5=OH, R2=R4=H (RAa, 0.6F)¹³³, 3,5,4′-Trihydroxyl derivatives: R1=R3=R5=H, R2=R4=OH (RAa<<0.1F)¹³³, 2,4,4′-Trihydroxyl derivatives: R1=R3=OH, R2=R4=R5=H (RAa<<0.1F)¹³³

Flavones, flavanones, and flavanols, nobiletin (5,6,7,8,3′,4′-hexamethoxyflavone), naringin (5,7,4′-trihydroxyflavanone), neohesperidin (5,7,3′-trihydroxy-4′-methoxyflavone^(102,103), neohesperidin in citrus fruit, Mulberroside F (moracin M-6,3′-di-O-□-glucopyranoside), norartocarpetin, Streppogenin (5,7,2′,4′-tetrahydroxy-flavavone, FIG. 3 d)¹⁰⁷, Dihydromorin (5,7,2′,4′)-tetrahydroxyflavanol, Artocarpetin (5,2′,4′-trihydroxy-7-methoxyflavone, isolated from the wood of Artocarpus heterophyllus ^(106,107), taxifolin (5,7,3′,4′)-tetrahydroxyflavano¹¹³, Garcinia subelliptica ¹¹⁴.

Isoflavonoids: seeds of Glycyrrhiza species (Leguminoseae): glabridin and glabrene¹¹⁵, Glyasperin C¹¹⁷, Aspergillus oryzae containes three hydroxyisoflavones-6-hydroxydaidzein (6,7,4′-trihydroxyisoflavone); -8-hydroxydaidzein (7,8,4′-trihydroxyisoflavone); and -8-hydroxygenistein (5,7,8,4′-tetrahydroxyisoflavone)^(118,119), Haginin A (2′,3′-dimethoxy-7,4′-dihdroxyisoflav-3-ene¹²¹, Dalbergioidin (5,7,2′,4′-tetrahyroxyisoflavan) isolated from L. cyrtobotrya ¹²², calycosin (4′-methoxy-7,4′-dihydroxyisoflavone¹²³.

Chalcones: Three chalcones derivatives, including licuraside, isoliquiritin, and licochalcone A, kuraridin, isolated from the plant Sophora flavescens kuraridinol, 2,4,2′,4′-tetrahydroxy-3-(3-methyl-2-butenyl)-chalcone (TMBC), 2,4,2′,4′-tetrahydroxychalcone.¹³¹

Stilbenes: Oxyresveratrol (2,4,3′,5′-tetrahydroxy-trans-stilbene)¹⁰⁶, Resveratrol (2,3′,5′-trihydroxy-trans-stilbene), Chloroporin (4-geranyl-3,5,2′,4′-tetrahydroxy-trans-stilbene)¹³⁶, Gnetol (2,6,3′,5′-tetrahydroxy-trans-stilbene)¹³⁷, piceatannol (3,5,3′,4′-tetrahydroxy-trans-stilbene)¹³⁸, Dihydrognetol¹³⁹, HNB [4-6-hydroxy-2-naphthyl)-1,3-bezendiol] New isostere of oxyresveratrol, HNB is the strongest tyrosinase inhibitor published until now.¹⁴⁵

Coumarins: Aloesin^(146,147), Esculetin¹⁴⁷, 9-hydroxy-4-methoxypsoralen 8′-epi-cleomiscosin A¹⁵¹, cleomiscosin A, Benzaldehyde and Benzoate Derivatives: benzoic acid, benzaldehyde, anisic acid, anisaldehyde, cinnamic acid, and methoxycinnamic acid from the roots of Pulsatilla cernua ¹⁵², 4-substituted benzaldehydes from cumin¹⁵³, 2-hydroxy-4-methoxybenzaldehyde from roots of Mondia whitei ¹⁵⁴, p-coumaric acid from the leaves of Panax ginseng ¹⁵⁵, hydroxycinnamoyl derivatives from green coffee beans¹⁵⁶, and vanillic acid and its derivatives from black rice bran¹⁵⁷, flourobenzaldehydes¹⁶¹, methyl trans-cinnamate¹⁶², salicylic acid¹⁶³, Hydroxybenzaldehydes¹⁶⁴, 4-□-D-glucopyranosyloxybenzoate¹⁶⁵, Protocatechualdehyde¹⁶⁶, protocatechualdehyde¹⁶⁷, Vinylbenzaldehyde¹⁶⁸, 4-alkylbenzaldehyde^(169,170), 2-hydroxy-4-isopropyl-benzaldehyde¹⁷¹, 3,4-dihydroxybenzaldehyde-O-ethyloxime¹⁷², 4-butyl-benzaldehyde thiosemicarbazone173, Gallic acid (3,4,5-trihydroxybenzoate)¹⁷⁴⁻¹⁷⁶, Gallic acid was also found to be very toxic to melanoma cells with cytotoxicity comparable to that of hydroquinone¹⁷⁷, flavonoids with gallate moiety bonded to the 3-hydroxyl position, including GCG [(+)-gallocatechin-3-O-gallate] and EGCG [(−)-epigallocatechin-3-O-gallate], were isolated from green tea leaves¹⁷⁹, Syntetic tyrosyl gallates¹⁸⁰, 1,2,3,4,6-pentagalloylglucopyranose isolated from the seed kernels of M. indica ¹⁷⁸, 1,2,3,4,6-pentagalloylglucopyranose isolated from the seed kernels of M. indica ¹⁷⁸ , Paeonia suffruticosa. ¹⁸¹

Long-chain Lipids and Steroids: Several lipids were purified from natural sources and exhibited tyrosinase inhibitory activity, including Triacylglycerol, trilinolein¹⁸², Glycosphingolipid, soyacerebroside I¹⁸³, Cerebroside B, from Phellinus linteus ¹⁶⁶, Trans geranic acid¹⁸⁴ , Trifolium balansae ¹⁸⁵, 2□(2S)-hydroxyl-7(E)-tritriacontenoate¹⁸⁶, Triterpenoid, 3□,21,22,23-tetrahydroxycycloart-24(31),25(26)-diene,¹⁸⁷ Triterpenoid glycosides¹⁸⁸, Pentacyclic triterpenes from the aerial part of the plant Rhododendron collettianum ¹⁸⁹, Diterpenoids from the aerial parts of Aconitum leave¹⁹⁰.

Lappaconitine hydrobromide, revealed activity similar to that of kojic acid¹⁹¹. Crocusatin-K, isolated from the petals of Crocus sativus ¹⁹² Sesquiterpenes from the leaves and stems of Chloranthus henryi, ¹⁹³ Sesquiterpenes dimmers from the leaves of Chloranthus tianmushanensis ¹⁹⁴, Hydroxylated steroid metabolites isolated from the fungus Cunninghamella elegans cultivations feeding with 17□-ethynyl- or 17□-ethylsteroids,¹⁹⁵

Other Natural and Synthetic Inhibitors from Other sources:

Anthraquinones: Physcion (1,8-dihydroxy-2-methoxy-3-methylanthraquinone)¹⁹⁶, 1,5-dihydroxy-7-methoxy-3-methylanthraquinone¹⁹⁷, lignans isolated from the roots of Vitex negundo, most active lignan from the plant (+)-lyoniresinol¹⁹⁸, Phloroglucinol derivative, dieckol, isolated from a marine brown alga, Ecklonia stolonifera ¹⁹⁹, marine-derived fungus Myrothecium sp. that contain 6-n-pentyl-□-pyrone²⁰⁰, Trichoderma viride strain H1-7, has competitive inhibition toward monophenolase activity of mushroom tyrosinase through binding to a copper active site of the enzyme.²⁰¹

Other inhibitors from synthetic sources: N-Phenylthiourea (PTU) and its derivatives^(202,203), Synthesized N-(phenylalkyl)cinnamides derived from the coupling cinnamic acid with phenylalkylamines²⁰⁴, Compounds by combining the structures of two putative tyrosinase inhibitors, kojic acid and caffeic acid²⁰⁵, Analogs of cupferron²⁰⁶, N-substituted-N-nitrosohydroxylamines²⁰⁷, N-hydroxybenzyl-N-nitrosohydroxylamines²⁰⁸, N-substituted-N-nitrosohydroxylamines²⁰⁹, sildenafil²¹⁰, oxadiazole²¹¹, oxazolones²¹², tetraketones types²¹³, 1,3-selenazol-4-one derivatives²¹⁴, Selenourea derivatives²¹⁵, Selenium-containing carbohydrates²¹⁶, 4,4′-Dihyldroxybiphenyl²¹⁷, glucoside derivatives from the fruit of Pyracantha fortuneana ²¹⁸.

In addition to directly inhibiting tyrosinase activity, 4,4′-dihyldroxybiphenyl was also found to suppress several cellular key parameters in the melanogenic pathway by downregulating the cAMP-dependent protein kinase K signaling pathway and decreasing gene expression of microphthalmia transcription factor, which in turn suppressed tyrosinase expression²¹⁹, S-phenyl N-phenylthiocarbamate²²⁰, 4-(2′,4′-dihydroxyphenyl)-(E)-3-buten-2-one.²²¹

Irreversible inactivators can form irreversible covalent bond with the target enzyme and then inactivate it. They are generally specific for tyrosinase and do not inactivate all proteins, they work by specifically altering the active site of the enzyme²²², including Captopril, an antihypertensive drug [(2S)-1-(3-mercapto-2-methylpropionyl)-L-proline]], forms both a copper-captopril complex and a disulfide bond between captopril and cysteine-rich domains at the active site of tyrosinase²²³ also as an inactivator of several copper-containing enzymes, such as dopamine β-monooxygenase²²⁴ and mushroom tyrosinase²²⁵, Cetylpyridinium chloride²²⁷, 3,5-dihydroxyphenyl decanoate²²⁸, p-hydroxybenzyl alcohol showed binding capability of mushroom tyrosinase and irreversibly inhibited the enzyme²²⁹, Hen egg white lysozyme (HEWL) inhibited mushroom tyrosinase with a reversibly and irreversibly mixed inhibition mechanism²³⁰.

Chemical structures of irreversible tyrosinase inhibitors:

These substrates belong to a special class. It is known that tyrosinase could be irreversibly inhibited by its o-diphenol substrates, such as L-dopa and catechol²³¹. These substrates were also named suicide substrates or mechanism-based inhibitors. The mechanism of the suicide substrate has been extensively studied by Waley²³². 7,8,4′-trihydroxyisoflavone and 5,7,8,4′-tetrahydroxyisoflavone are potent and unique suicide substrates of mushroom tyrosinase¹²⁰, and 5,7,8,4′-tetrahydroxyisoflavone is the most potent suicide substrate of mushroom tyrosinase until now and has high potential in application as a skin-whitening agent²³⁶.

It has been found that in humans eye color is directly dependent upon the amount of pigment granules of melanine and the number of melanocytes of the iris stroma. For example, with little or no pigment the eye looks blue, with more pigment the eye looks green, with more pigment the eye looks hazel and even more pigment yields brown or black color.

Duplicating and greatly expediting the natural process of depigmentation of the iris requires many disparate approaches and techniques. Multiple steps of melanogenesis may need to be addressed and inhibited. This may include stopping the sympathetic or other parasympathetic nerve impulses from reaching the melanocytes, blocking the conversion of tyrosine to eumelanin, and interfering with the various means of melanin production, such as inhibiting the cyclooxigenase-2 (COX-2) enzyme and melanocyte stimulating hormone (MSH), or other biological processes. One major advantage of the iridial melanocytes is that access to the melanocytes themselves and their underlying synaptic connections is easily achieved by continuity with the fluid in the aqueous humor in the anterior compartment of the eye, since the anterior iris lacks an epithelium or basement membrane. This leaves the iridial melanoctyes bathed in and completely exposed to the aqeous humor environment.

In addition to inhibition of tyrosinase catalytic activity, other approaches to decrease iris pigmentation include denervation of melanocytes, inhibition of tyrosinase mRNA transcription, aberration of tyrosinase glycosylation and maturation, acceleration of tyrosinase degradation, interference with melanosome PH, maturation and pigment accumulation, and inhibition of inflammation-induced melanogenic response.

In one embodiment, a method and system are described for inducing ocular hypopigmentation of the eye, in other words, decreasing or altering the pigmentation of the conjunctiva or iris, or both. The novel method involves the use of a known drug, hydroquinone that has not heretofore been known to have been used for inducing hypopigmentation in the eye, in either the conjunctiva or iris. (http://www.drugs.com/cdi/hydroquinone-cream.html; http://www.pesticideinfo.org/Detail_Chemical.isp?Rec_Id=PC35626). The use of hydroquinone in a technique or composition non-toxic to the eye can result in making the white part of the eyes very white and lightening the otherwise darkening color of the iris during current treatment protocols for glaucoma based upon prostaglandin analogs. Whiter eyes are a desirable symbol of youthfulness and therefore highly acceptable to an aging population.

In one embodiment, a human subject is treated with 1% Memantine, 0.5% Thymoxamine, 10% Oxyresveratrol, and 2% Pilocarpine.

In another embodiment, a human subject is treated with 2% Memantine, 1% Thymoxamine, 0.09% Bromfenac, and 20% Oxyresveratrol.

In yet another embodiment, a human subject is treated with 1% Memantine, 0.09% Bromfenac, 0.5% Thymoxamine, 5% H89, and 0.5% Naloxone.

In yet another embodiment, a human subject is treated with 1-Latanoprost ophthalmic solution 0.005%, 2-Forskolin eye drop 1%, and 3-Ophthalmic suspension of 1-oleoyl-2-acetyl-glycerol 0.5%.

In studies of macular degeneration it has been shown that there is a significant association between light iris color, fundus pigmentation and the incidence of macular degeneration. It is known that zinc will bind to melanin in pigmented tissues and will thereby enhance antioxidant capacity as a cofactor or gene expression factor of antioxidant enzymes in the eye. This has been shown in an investigation of the uptake and storage of zinc in human irides, namely irides of blue and brown human eyes.¹ In this study, the irides were incubated with concentrations of zinc chloride and tissue specimens were examined for the storage of zinc. It was found that the melanocytes count was significantly higher in brown tissues. No significant storage of zinc was found in blue colored irides. It was concluded that zinc uptake is dependent upon the extent of pigmentation in the iris of the human eye. Accordingly, the degree of pigmentation of a patient's eyes must be considered with respect to the effectiveness of a possible treatment for macular degeneration with a zinc supplementation. A significant aspect of this study is the conclusion that zinc uptake is more prevalent with respect to darker pigmentation or discoloration of the conjunctiva or iris of the eye. However, for the purpose of altering eye color, a delivery system using zinc to provide color-altering compositions to the conjunctiva and. iris of the eye has not heretofore been realized. Similarly, with respect to altering the color of the skin and hair, there have heretofore been available only topical applications of a large variety of compositions, with limited effectiveness and longevity.

Drug delivery systems (DDS) based upon using nanoparticles to carry drugs have been known heretofore (http://www.nano.gatech.edu/about; http://web.mit.edu/newsoffice/2008/nanocell-0609.html; http://www.scientistlive.com/European-Science-News/Nanotechnology/Melanoma_destroying). Nanoparticles are stable, have a large capacity for carrying drugs and can incorporate both hydrophilic and hydrophobic substances. Nanoparticles have been used as drug carriers for hydrophilic and hydrophobic substances, and have been found feasible for various routes of administration. Nanoparticles are also known to allow controlled drug release over therapeutically appropriate periods of time.

There have been many instances of nanoparticle Drug Delivery Systems (DDS) that transport toxic medications safely to targeted tissue without affecting the surrounding tissue. Examples include a Tuberculosis (TB) drug delivery system¹⁷, cancer treatment¹⁶, and fungal infections²². Nanoparticles have been used to target cancer tumors or other sources of disease, such as tuberculosis. Nanoparticle-based drug-delivery systems have also demonstrated efficacy in the treatment of breast cancer. For example, tamoxifen encapsulated in polyethylene glycol molecules has been used for penetrating tumors. Inorganic nanoshells can be combined with and carry bioactive biomolecules for targeted tumor penetration and photothermal-based anticancer therapy. In one study concerning the eyes, polycyanoacrylate nanoparticles were used to improve the corneal penetration of hydrophilic drugs. A higher concentration of amikacin in the cornea and aqueous humour was found to be statistically significant over a control solution when the amikacin was placed in a nanoparticle formulation.

A nanoparticle DDS requires a specific mechanism to be targeted to the desired cell type. Zinc has been shown to have predilection to be absorbed by the melanocytes of the iris.⁶ Hence, zinc can be used as a tagging agent to target melanocytes, and if the drug were administered to the eye or anterior chamber specifically, the predominate uptake would likely be by iridial melanocytes. There are many types of nanoparticles or nanoshells made of zinc itself, and others that are tagged with zinc, which can be used as a transport system for transferring the above medications directly to the melanocytes of the iris without affecting the surrounding ocular tissues.

The biomedical applications for inorganic nanoparticles are relatively recent. Inorganic nanoparticles have a metal core or a metal shell that may serve as a substrate for joining with biomolecules. Single crystal zinc oxide has been formed into nanorings, having a uniform and perfect geometrical shape.

In one embodiment, ocular nanoparticles, for example of zinc oxide or other forms of zinc, may be combined with a pharmaceutically effective composition and concentration of hydroquinone and delivered to discolored eyes resulting from standard glaucoma treatments. Such nanoparticles which include zinc will, accordingly, target the melanocytes and bind to melanin in pigmented tissues. In such circumstances, there will be no toxic effect on surrounding eye tissue caused by the release of hydroquinone to cells defining the discolored tissues. The hydroquinone changes the amount of the pigment, for example, of the iris without any affect on the surrounding tissue. Ocular nanoparticles may be delivered to the eye in the form of eye drops, or may be delivered systemically.

Alternatively, ocular nanoparticles formed from a zinc compound may be used to deliver glaucoma medications directly to the ciliary bodies. Such a delivery system avoids both a toxic impact to eye tissue caused by hydroquinone, and avoids discoloration of the iris that would otherwise occur as a result of the application of glaucoma medication.

Proposed medicinal therapeutics can reach iridial melanocytes via topical administration to the eye with subsequent absorption into the anterior chamber, direct injection into the anterior chamber, or systemic administration, preferably with a method to enrich or target iridial melanocyte uptake. For example, botulinum toxin may also be used to block nerve transmission at synaptic level¹⁵ by transporting the toxin molecules safely with nanoparticle DDS (Drug Delivery System)¹⁶⁻¹⁸ that is conjugated in a covalent or non-covalent manner with a targeting agent such as zinc^(6,7), which is known to be preferentially taken up and stored by melanocytes. Similarly, gold nanoparticles with PEGylated anti-melaoncyte antibodies have been used to treat melanoma³⁶, and a similar strategy could be employed here. When used in combination with tyrosinase inhibitors⁸, COX-2 inhibitors,⁹⁻¹¹ cholinergic agonists¹ such as pilocarpine, and new bleaching agents such as Zinc Glycoprotein^(12,13) and DMHF,¹⁴ depigmentation of the iris may be successfully achieved. In an embodiment, over-saturating the molecule carriers can be used to overcome the inter-cellular outward flow and maximize the transport of molecules into the anterior chamber. In another embodiment, microneedles can be used to directly inject medication into the anterior chamber to bypass the superficial part of the sclera which is infiltrated with lymphatic draining vessels (superficial ⅓rd). In yet another embodiment, Folate receptors can also be used to carry small and large molecules inside the melanocytes. The presence of Folate Receptor-α in normal and pathological melanocytes has been identified. It has been demonstrated that Methotrexate is preferentially transported through this receptor in melanoma cells. It has also been demonstrated that cells expressing the human Folate receptor internalize a higher level of nanoparticles. (Luís Sánchez-del-Campo, María F. Montenegro, Juan Cabezas-Herrera and José Neptuno Rodríguez-López, “The critical role of alpha-folate receptor in the resistance of melanoma to methotrexate”, Pigment Cell & Melanoma Research, (2009) Vol. 22, No. 5, Pg 588-600).

The nanoparticles can be initially surface-modified with (3-aminopropyl) trimethoxysilane to form a self-assembled monolayer and subsequently conjugated with desired medication through amidation between the carboxylic acid end groups on the medication, and the amine groups on the particle surface. Moreover, the nanoparticles should be under low pH conditions mimicking the intracellular conditions in the lysosome for ease of drug delivery. (Nathan Kohler, Conroy Sun, Jassy Wang, and Miqin Zhang, “Methotrexate-Modified Superparamagnetic Nanoparticles and Their Intracellular Uptake into Human Cancer Cells”, Langmuir, (2005) 21(19), pg. 8858-8864).

Since melanoma is a cancer in pigmented cells, melanoma cancer has and does occur in the eye. For example, it can occur on the iris, a ciliary body or on the choroid behind the retina. Such locations for malignant melanoma have heretofore led to a very poor prognosis for survival. Nanoparticles that contain an appropriate form of zinc can be used to target cancerous pigmented cells in or around the eye and carry anti-cancer medication that would be absorbed in the melanin of the pigmented cancer cells and therefore will affect only the pigmented cancerous cells, even if it would otherwise be toxic to normal non-pigmented cells. Normal pigmented cells would not be affected by such anti-cancer therapy when the nanoparticles are adjusted for specific cancer cell receptors.

In the case of hair, nanoparticles of a suitable form of zinc and tagged with a suitable and effective form of hydroquinone can be applied topically to the scalp. The zinc targets and binds to the melanocytes in the roots of hair follicles thereby to cause the color of the hair to change. No dying of the hair to change its color would be necessary. Because zinc binds to melanin in pigmented tissue, such nanotechnology including hydroquinone may be used systemically to affect a change in the color of hair.

Similarly, an appropriate zinc nanoparticle tagged with an effective composition and concentration of hydroquinone can be used to target and bind to melanocytes in the skin, thereby to effect an alteration in the color of the pigmented cells. The hydroquinone is carried to and will act directly on the pigmented skin cells to change the color of the skin, e.g., to make it lighter in color. Hydroquinone with nanotechnology including zinc nanoparticles to target melanocytes in the skin can be topically applied to the skin as a cream. In addition, hydroquinone with nanotechnology including zinc nanoparticles to target melanocytes in the skin can be used systemically to achieve the same results. Thus, an effective nanotechnological composition can be adjusted and delivered systemically so that the zinc element binds to melanocytes of pigmented cells in the skin and the hair, thereby to permit the hydroquinone to change the color of the skin and hair simultaneously.

Of course, malignant melanoma occurs prevalently in the pigmented cells of the skin. As indicated, a zinc nanotransfer drug delivery system can be used to treat melanoma. Nanoparticles that contain an appropriate form of zinc can be used to target cancerous pigmented cells in the skin and carry anti-cancer medication that would be absorbed in the melanin of the pigmented cancer cells and therefore will affect only the pigmented cancerous cells even if it would otherwise be toxic to normal non-pigmented cells. Normal pigmented cells would not be affected by such anti-cancer therapy when the nanoparticles are adjusted for specific cancer cell receptors.

The fundamental structure of hair and nails is essentially the same. Accordingly, if a zinc nanoparticle is tagged with a suitable antibiotic or antifungal drug, the targeting of pigmented nail cells by zinc nanoparticles will deliver the drug systemically to the nail as a treatment for various nail infections.

It will be understood that using nanoparticles with targeting agents such as zinc can permit using toxic medications or toxic solutions to be safely delivered to target tissues without adversely affecting other tissues. This technique can be used to deliver very toxic medications directly and safely to target pigmented cells. In addition to zinc, other targeting agents including antibody, ligand specific targeting agents, magnetic targeting agents can also be used. Furthermore, nanoparticles can be passively transported to the target tissue and deliver the small molecules. While the foregoing description involves the use of zinc nanoparticles to carry the appropriate composition of the drug of interest, other techniques may be used without departing from the scope of the invention. For example, instead of using a zinc nanoparticle, a nanoparticle carrying hydroquinone could be tagged with a zinc composition. Moreover, any drug that affects or would alter pigmentation of tissue can be used with zinc either as a tag to a zinc nanoparticle or in the form of a nanoparticle tagged with a suitable form of zinc. Different drugs such as antibiotics or a composition of tyrosinase inhibitors can be used with zinc in various treatment protocols.

In an embodiment, a method consists of introducing to pigmented tissue a pharmaceutically acceptable toxic or non-toxic solution of hydroquinone or suitable derivative thereof. Hydroquinone is a reducing agent soluble in water. Hydroquinone is known heretofore to be used as a topical application to the skin for whitening or reducing the color of skin. Hydroquinone has not been known heretofore to be used as or as part of an ophthalmic drug delivery system for the eye either in an appropriate eye drop solution or as a compositional time-release coating for inserts to the eye. Nor has hydroquinone been known to be used heretofore as a nanoparticle tagged with a suitable zinc composition nor associated with a suitable nanoparticle of zinc to bind to the melanocytes in the pigmented skin of the eye, hair, skin or nails.

In a carrier appropriate for the eye, hydroquinone will have the effect of reducing pigmentation in ocular melanocytes, as well as lightening the color of the iris, thereby reversing the darkening effect of glaucoma medications and improving cosmetic affects and possibly assisting in the treatment of heterochromia in an appropriate eye drop solution. As indicated, a nanoparticle transport system may be used to deliver glaucoma medications directly to the ciliary bodies to avoid the darkening effect of some standard glaucoma medications.

The composition of hydroquinone by itself is known. Hydroquinone is also known as benzene-1,4-diol or quinol and is an aromatic organic compound which is a type of phenol, having the chemical formula C₆H₄(OH)₂. Its chemical structure has two hydroxyl groups bonded to a benzene ring in a para position. Its chemical structure is shown in a table attached hereto and incorporated by reference herein. It is a white granular solid at room temperature and pressure. In a pharmaceutically acceptable liquid solution, such as but not limited to water, hydroquinone or its suitable derivative may be introduced into the eye, in one embodiment as an eye drop.

In one embodiment, the method may consist of introducing into the eye a pharmaceutically acceptable non-toxic composition of hydroquinone in the form of a salve, cream, emulsion, gel or other solution. Since solutions, creams, emulsions or gels consisting of hydroquinone for purposes of skin-bleaching have heretofore been found to be somewhat toxic to the eyes, existing compositions or formulations including hydroquinone therefore teach away from introducing to the pigment of the eye pharmaceutically acceptable toxic and non-toxic compositions of hydroquinone for reducing pigmentation in ocular melanocytes or reducing dark color areas formed in the conjunctiva or iris as a result of many standard glaucoma medicines. Moreover, the art does not teach or suggest the use of hydroquinone with respect to nanotechnology nor in particular the combination of hydroquinone with a suitable zinc nanoparticle or hydroquinone nanoparticles tagged with zinc to target and bind to the melanocytes in pigmented body tissue for changing pigment color. Nor does the art disclose or suggest nanotransfers of medication combined with forms of zinc for treating diseases of pigmented skin, such as malignant melanoma. Nanotransfers using zinc to target melanin in pigmented cells may be utilized to deliver toxic or non-toxic drug compositions to the targeted cells without adversely affecting healthy tissues.

In an embodiment, hydroquinone may be used in the eye as a component of a coated insert. Coated inserts have been known heretofore to deliver other ophthalmic drugs (Sasaki et al., (2003) “One-side-coated inser as a unique ophthalmic drug delivery system”, Journal of Controlled Release, Vol. 92(3), pages 241-247). Some inserts coated with other ophthalmic drugs have heretofore have been one-side-coated. It may also be possible to have an insert that is coated on two sides, depending on the drug composition used, its time release properties and its strength. In an embodiment, a pharmaceutically acceptable non-toxic composition of hydroquinone may be used uniquely in connection with a one-sided coated insert. In such circumstances, the result is a time-release ocular and systemic absorption of the effective solution or composition of hydroquinone. This may result in higher drug concentrations in the aqueous humor and sclera, and lower drug concentrations in the plasma and conjunctiva than has been reported for the use of other drugs heretofore. The ocular and systemic absorption of a suitable hydroquinone composition or composite solution delivered by a one-sided-coated insert may be altered by the direction of insertion.

It will be understood that the nanoparticle transfer system and method described herein and based upon zinc or zinc compound nanoparticles may be used for any cosmetic or therapeutic treatment involving pigmented tissue without departing from the scope of the invention. Indeed, any kind of nanoparticle that is tagged with zinc can carry hydroquinone and/or anti-cancer medications to the pigmented tissues. With respect to treatments for cancer see, for example, see http://www.scientistlive.com/European-Science-News/Nanotechnology/Melanoma_destroying_nanospheres/21648/. Such articles and the others attached hereto are incorporated by reference.

Following the bleaching process of the iris as described herein, different methods of dying the eyes can be implemented to change the color of the eyes to varying hues and shades of color. This includes enhancing natural coloring such as deepening the blue or green hues, as well as unnatural colors such as purple, metallic gold or silver, or even fluorescent colors which glow in darkness or in black light (UV).

The following small molecules can be used for opposite effect, in order to darkening the color of the eye or reverse the previously lightened eye.

-   1. Topical prostaglandin (PG) F2α analogues are potent medications     for managing elevated intraocular pressure (IOP). One side effect of     these drugs is a darkening of iris color. (Zhan et al., 2003). -   2. Forskolin (Naturally occurring molecule) and     isobutylmethylxanthine (IBMX)(Synthetic compound) are known to     regulate adenylyl cyclase and phosphodiestherases, resulting in an     increase in melanin biosynthesis in melanocytes. (Brian R. et al.,     2009). -   3. 1-oleoyl-2-acetylglycerol, or OAG,(the naturally-occurring) and     1,2-diacylglycerol, (synthetic, or DAG). DAG's analogues and     derivatives are able to induce melanin synthesis and thus produce an     increase in melanin content in melanocytes.(U.S. Pat. No.     5,352,440). -   4. Lotus (Nelumbo nuficera) flower essential oil increased     melanogenesis in normal human melanocytes (Songhee Jeon et al., July     2009).

The subject application describes a method of lightening the color of the iris of a human subject. In this method, a composition of a tyrosinase inhibitor is administered to the iris of a human subject in an amount effective to lighten the color of the iris.

In an embodiment of the method, the tyrosinase inhibitor is hydroquinone, oxyresveratrol or tetrahydroxyisoflavone, preferably hydroquinone.

In another embodiment of the method, the composition can also contain at least one melanogenesis inhibitor, which are selected from the group of a glutamate receptor blocker (e.g. memantine), an α-adrenergic blocker (e.g. thymoxamine), a matrix metalloproteinases inhibitor (e.g. prinomastat), a Cox inhibitor (e.g. bromfenac), a cholinergic agonist (e.g. pilocarpine), a downregulator of mitf, tyr & Trp1 (e.g. Haginin A or 4,4′-dihyldroxybiphenyl), an acidifier of melanosomes (e.g. H89), an opioid receptor antagonist (e.g. naloxone), a Pmel17 blocker (e.g. calmodulin inhibitors), and a fibroblast growth factor inhibitor. In particular, the composition contains hydroquinone, memantine and Haginin A; oxyresveratrol, 4,4′-dihyldroxybiphenyl and H89; or tetrahydroxyisoflavone, prinomastat and naloxone.

In yet another embodiment of the method, the composition can be administered to a human subject in conjunction with an injection of saline, siRNA, botulinum toxin, or a combination of botulinum toxin and siRNA.

The methods described herein can be administered through a nanoparticle drug delivery system containing a targeting agent of iridial melanocytes. The targeting agents include a composition of zinc, antibody, ligand specific targeting agents, magnetic targeting agents, preferably a composition of zinc such as zinc oxide. The composition described herein can be in the form of eye drops or an ophthalmic drug delivery system such as salves, creams, emulsions and gels. The composition described herein can be administered in the fornices under the eyelid or as a time-release coated insert which is coated on at least one side.

The method described herein can be administered to a healthy human or a human subject afflicted with glaucoma.

The subject application also describes a method of introducing pigments to the iris of a human subject. In this method, at least one melanogenesis promoter is administered to the iris of a human subject in an amount effective to introduce pigments to the iris. The iris of the to human subject becomes darker after such treatment.

In an embodiment of the method, the melanogenesis promoter includes prostaglandin, forskolin, 1-oleoyl-2-acetylglycerol and 1,2-diacylglycerol, and lotus flower essential oil.

The subject application further describes a method of introducing pigments to the iris of a human subject. In this method, a composition comprising a biological dye is administered to the iris of a human subject in an amount effective to introduce pigments to the iris. In an embodiment, the biological dye is Trypan Blue or a Methyl Green biological dye.

In another embodiment of the method, the composition can also contain fluorescein. The iris of the human subject changes color and/or glows after such treatment.

In yet another embodiment of the method, the composition is administered through a nanoparticle drug delivery system containing a targeting agent of iridial melanocytes, preferably the targeting agent is a composition of zinc such as zinc oxide.

The subject application yet further describes a nanoparticle composition for lightening pigmented tissues. This nanoparticle composition contains a targeting agent of melanocytes chemically bound to a pharmaceutical composition comprising a tyrosinase inhibitor. The targeting agents include a composition of zinc, antibody, ligand specific targeting agents, magnetic targeting agents, preferably a composition of zinc such as zinc oxide.

In an embodiment of the nanoparticle composition, the tyrosinase inhibitor is hydroquinone, oxyresveratrol or tetrahydroxyisoflavone, preferably hydroquinone.

In another embodiment of the nanoparticle composition, the pharmaceutical composition can also contain at least one melanogenesis inhibitor.

In yet another embodiment of the nanoparticle composition, the pigmented tissues are skin or hair tissues.

In yet another embodiment, the nanoparticle composition is in the form of an injectable solution or a topically applied solution.

The subject application yet further describes a method for lightening pigmented tissuess of a human subject. In this method, the nanoparticle composition described herein is administered to the human subject so as to lighten the pigmented tissues.

The subject application yet further describes another nanoparticle composition for treating a pigmented tissue related disease. This nanoparticle composition contains a targeting agent of melanocytes chemically bound to a pharmaceutical composition containing an active agent for the disease. The targeting agents include a composition of zinc, antibody, ligand specific targeting agents, magnetic targeting agents, preferably a composition of zinc such as to zinc oxide.

In an embodiment of the method, the disease is glaucoma or melanoma cancer.

The subject application yet further describes a method for treating a pigmented tissue related disease. In this method, the nanoparticle composition described herein is administered to a human subject afflicted with a pigmented tissue related disease so as to treat the disease.

In the methods described herein, the targeting agent binds to cells of the pigmented tissues to permit the release of the pharmaceutical composition directly into the cells of the pigmented tissue without affecting non-pigmented cells.

The subject application yet further describes a method of depigmenting the iris melanocytes to lighten the color of the iris. This method includes the use of one or more of the following steps:

-   -   Blocking the sympathetic and parasympathetic nerve supply to the         melanocytes using botulinum toxin and memantine;     -   Preventing tyrosine conversion to melanin by one of available         tyrosinase inhibitors;     -   Preventing Melanocyte-stimulating hormone activation (MSH) by         using 2,5-Dimethyl-4-hydroxy-3(2H)-furanone (DMHF);     -   Inhibiting the COX-2 enzyme using NSAIDS;     -   Preventing melanogenesis by using a cholinergic agonist;     -   Blocking Alpha 1-adrenergic receptors by using antagonist         chemicals.

As used herein, a melanogenesis inhibitor refers to a compound that inhibits any step of melanogenesis. For example, a melanogenesis inhibitor inhibits conversion from Dopaquinone to 5-S-Cysteinyldopa; conversion from 5-S-Cysteinyldopa to 5-S-Cysteinyklopa, conversion from 5-S-Cysteinyklopa to Benxothiazine intermediaries, conversion from Benxothiazine intermediaries to Pheomelanin, conversion from 5-S-Cysteinyklopa to Pheomelanin, conversion from 5-S-Cysteinyklopa to Pheomelanin, conversion from Dopaquinone to Leucodopachrome, conversion from Dopaquinone to Eumelanin, conversion from Leucodopachrome to Eumelanin, conversion from Leucodopachrome to Dopachrome, conversion from Leucodopachrome to Dopachrome, conversion from Dopachrome to Eumelanin, conversion from Dopachrome to 5,6-Dihydroxyindole-2-carboxylic acid, conversion from Dopachrome to 5,6-Dihydroxyindole, conversion from 5,6-Dihydroxyindole-2-carboxylic acid to Eumelanin, conversion from 5,6-Dihydroxyindole to Eumelanin, conversion from 5,6-Dihydroxyindole to Indole-5,6-quinone-carboxylic acid, or conversion from Indole-5,6-quinone to Eumelanin. A melanogenesis inhibitor also optionally includes Tyrosinase inhibitors, which inhibit conversion from Tyrosine to Dopa or from Dopa to Tyrosinease.

As used herein, a melanogenesis promoter refers to a compound that activates any step of melanogenesis. For example, a melanogenesis promoter activates conversion from Dopaquinone to 5-S-Cysteinyldopa; conversion from 5-S-Cysteinyldopa to 5-S-Cysteinyklopa, conversion from 5-S-Cysteinyklopa to Benxothiazine intermediaries, conversion from Benxothiazine intermediaries to Pheomelanin, conversion from 5-S-Cysteinyklopa to Pheomelanin, conversion from 5-S-Cysteinyklopa to Pheomelanin, conversion from Dopaquinone to Leucodopachrome, conversion from Dopaquinone to Eumelanin, conversion from Leucodopachrome to Eumelanin, conversion from Leucodopachrome to Dopachrome, conversion from Leucodopachrome to Dopachrome, conversion from Dopachrome to Eumelanin, conversion from Dopachrome to 5,6-Dihydroxyindole-2-carboxylic acid, conversion from Dopachrome to 5,6-Dihydroxyindole, conversion from 5,6-Dihydroxyindole-2-carboxylic acid to Eumelanin, conversion from 5,6-Dihydroxyindole to Eumelanin, conversion from 5,6-Dihydroxyindole to Indole-5,6-quinone-carboxylic acid, or conversion from Indole-5,6-quinone to Eumelanin. A melanogenesis promoter also activates conversion from Tyrosine to Dopa or from Dopa to Tyrosinease.

As used herein, a targeting agent of a certain cell type (e.g. melanocytes) refers to an agent (e.g. a molecule or a composition of a molecule) which is preferential taken up and stored by the cell type.

As used herein, a targeting agent “chemically bound” to a pharmaceutical agent refers to the targeting agent is conjugated with the pharmaceutical agent in a covalent or non-covalent manner.

As used herein, a pigmented tissue related disease refers to a disease in which diseased cells reside in pigmented tissues.

This invention will be better understood from the experimental details which follow. However, one skilled in the art will readily appreciate that the specific methods and results discussed are merely illustrative of the invention as described more fully in the claims which follow thereafter.

EXPERIMENTAL DETAILS I. Bleaching A. Active Agents

The following list contains a partial list of drugs can be tested for use in bleaching and/or coloring.

-   1. Tyrosinase inhibitor* -   2. Glutamate receptor blocker (Memantine)(CAS) -   3. α-adrenergic blocker (Thymoxamine)(CAS) -   4. Cox inhibitor (Bromfenac)* -   5. Cholinergic agonist (Pilocarpine)(CAO) -   6. Downregulator of mitf, tyr & Trp1 (Haginin A)(CAD)* -   7. Acidifier of melanosomes (H89)* -   8. matrix metalloproteinases inhibitor (prinomastat) -   9. Opioid receptor antagonist (Naloxone)* -   10. Pmel17 blocker (Calmodulin inhibitors)* -   11. Fibroblast growth factor inhibitor* -   12. siRNA gene silencing

Various combinations of the drugs are tested using cell culture in vitro (*) and the most effective combinations are chosen for animal studies.

In animal studies, the most effective combinations from in vitro studies are used in conjunction with various combinations of the remaining therapies (those not marked with *).

B. Transport System

The following is a list of methods that can be used to deliver to the iris of any one or any combination of the above listed small molecules.

-   1. Topical (A. S. Mundada, PharmaInfo.net, Vol. 6, Issue 1, 2008)     -   a. Conventional         -   i. Ointments         -   ii. Solutions         -   iii. Suspensions         -   iv. Gels         -   v. Emulsions         -   vi. Inserts (erodible and non-erodible)     -   b. Recent         -   i. Penetration Enhancers         -   ii. Mucoadhesive Polymers         -   iii. In Situ Gelling Systems         -   iv. Colloidal systems         -   v. Iontophorosis         -   vi. Nanoparticles (e.g. Fullerenes and Carbon Nanotubes,             Liposomes, Nanoshells, Dendrimers, Superparamagnetic             Nanoparticles, Nanorods, Quantum Dots) -   2. Injectable (subconjunctival, subtenon, intravitreal, intravenous)     -   a. Solutions     -   b. Suspensions     -   c. Gels     -   d. Emulsions     -   e. Inserts     -   f. Nanoparticles

C. Targeting and Vehicles

The following is a sampling of targeting mechanisms and vehicles used that could be used to deliver to specific target cells or organelles, i.e. melanocytes or melanosomes via topical eye drops or microneedle injection. Once the vehicle is delivered to the destination, it can be released through various means, such as photodynamic therapy (PDT) (Drug Discov Today. 2008 February; 13(3-4): 124-134), pH sensitive drug delivery (Journal of Controlled Release, Volume 103, Issue 1, 2 Mar. 2005, Pages 137-148), and thermally sensitive drug delivery (K. S. Soppimath, D. C.-W. Tan, Y.-Y. Yang, pH-Triggered Thermally Responsive Polymer Core-Shell Nanoparticles for Drug Delivery, Volume 17 Issue 3, Pages 318-323)

-   1. Containers     -   a. Positively Charged Dendrimers     -    Positively charged Dendrimers cause membrane defects which leak         cellular proteins and through which particles can pass.     -   b. Liposomes     -    “Liposomes are microscopic and submicroscopic vesicles with         sizes ranging from 10 nm to 20 μm. They are usually made up of         phospholipids, although other amphiphiles such as nonionic         surfactants can also be employed for their construction. When         phospholipids are hydrated, they spontaneously form spherical         lipid bilayers enclosing the aqueous medium and the solute.         Liposomes offer several advantages over other delivery systems         including biocompatibility, control of biological properties via         modification of physical properties (e.g., lipid composition,         vesicle size, lipid membrane fluidity etc.) and several modes         for drug delivery to cells (e.g., absorption, fuse, endocytosis,         phagocytosis). Liposomes can be classified according to the         number of the lipid bilayers as unilamellar vesicles (ULVs) and         multilamellar vesicles (MLVs). Functionalized liposomes can be         synthesized using peptides and oligosaccharides in order to         achieve both targeting and circulation longevity. Peptides can         be used in order to guide liposomes to desired receptors         whereas, poly(ethylene oxide) (PEO)-grafted phospholipids are         known to dramatically increase liposome survival in the         circulation. A surface modified liposomal drug delivery vehicle         can be developed for selective targeting by coupling an         argentine-glycine-aspartic acid (RGD) peptide to the liposome         through a PEO spacer.”⁴⁹     -   c. Cell Penetrating Peptides     -    Cell penetrating peptides are short peptides that facilitate         cellular uptake of molecular cargo from small molecules to         nanoparticles and large DNA fragments.

 “Various in vitro and in vivo studies have proved the potential of cell-penetrating peptides (CPPs), including TAT peptide (TATp) and oligoarginines, for the intracellular delivery of different cargoes. TATp-mediated cytoplasmic uptake of polymers (Nori et al. 2003; Hyndman et al. 2004), bacteriophages (Paschke et al. 2005), plasmid DNA (Torchilin et al. 2001, 2003; Kleemann et al. 2005), magnetic nanoparticles (Dodd et al. 2001; Zhao et al. 2002; Nitin et al. 2004), liposomes (Cryan et al. 2006; Sawant et al. 2006; Gupta et al. 2007), and micelles (Sawant et al. 2006; Sethuraman et al. 2007, 2008) has been reported. Successful intracellular delivery requires direct contact between the surface-attached CPPs on the pharmaceutical nanocarrier and the cell surface” (Torchilin et al. 2001; Levchenko et al. 2003

-   -   d. Receptor-Mediated Endocytosis     -    Receptor-mediated Endocytosis is a process by which cells         internalize molecules by the inward budding of plasma membrane         vesicles containing proteins with receptor sites which         specifically bind to the molecules being internalized. (Nature         Reviews Molecular Cell Biology 6, 112-126 (February 2005)|         doi:10.1038/nrm1571)

-   2. Targeting Agent     -   a. Zinc     -    The high concentration of Zn(II) ion inside the melanosomes may         create a good target for a transport system utilizing zinc         fingers (ligands) to deliver a payload of drugs specifically to         the melanosomes.     -    “Zinc is a feature trace element of pigment cells and tissues.         Organelles, in which melanin is synthesized and stored, i.e.         melanosomes, represent a zinc reservoir at the subcellular         level. In order to understand function of metals in tissues,         cells and their constituents, knowledge is needed on metal         interactions with intracellular targets. The possible zinc         ligands in pigment cells include melanin, metallothionein,         melanotransferrin, B700 and related proteins, ferritin, zinc         enzymes and low molecular weight ligands. Areas of a special         interest in relation of pigment cells and structures to         zinc—such as zinc effect on melanogenesis, zinc excretion and         buffering by melanosomes, zinc function in free radical         processes as well as zinc role in melanomas—have been reviewed.         High level of zinc in pigment cells may indicate a physiological         defense against the potential danger of oxidative stress.”⁵⁰     -   b. Antibodies     -    Antibodies to Melanin can be used to specifically target         Melanosomes. Antibodies currently under investigation or in use         include melanin-binding IgM antibody from Goodwin Biotechnology         Inc., murine monoclonal antibodies⁵¹, and monoclonal antibody         6D2⁵².     -    Depending on the drug to be delivered, different methods can be         used to associate the drug with the antibody, such as         Polymer^(53,54), Liposome⁵⁵, and Dendrimer⁵⁶

II. Coloring and Texturing

Using the transport and targeting systems described herein, pigments and/or dyes (including fluorescent, metallic, and other dyes and pigments) or other chemicals are introduced, to change directly or indirectly the appearance of the iris.

If the natural color of the eye does not permit the desired change, then bleaching step as described herein may be done prior to or in conjunction with the texturing and coloring.

1. Targeting

Unlike in Bleaching step described herein, our targets are expanded to include connective tissue or the anterior surface of the iris, including collagen⁵⁷, fibroblasts, interstitial matrix, and vascular tissue. The targeting mechanism has very high specificity for the above targets in order to prevent unwanted color change of the other parts of the eye including the cornea and the lens. This is achieved through selection of the appropriate antibodies, collagen adhesives (e.g. U.S. Pat. No. 5,219,895), and tissue adhesives⁵⁸.

2. Containers

Common biological stains and/or fluorescent materials such as Fluorescein sodium dye⁵⁹ are encapsulated in nanoparticles such as liposomes as described herein, and targeted with mechanisms explained above.

Standard techniques for loading the dye cargo into the liposomes can be used.⁶⁰

EXAMPLE 1 Cell Cultures

Typical cell culture methods and measurement of tyrosinase activity and statistical analysis may be employed, as described in Yeon Mi Kin et al.⁶⁶

A. Culture of Murine Melanoma B-16

The cells can be grown in DMEM (13.4 mg/ml Dulbecco's modified Eagle's medium, 24 mM NaHCO3, 10 mM HEPES, 143 units/ml penicillin G potassium, 100 μg/ml streptomycin sulfate, pH 7.1) containing 10% FBS with 5% CO2 at 37° C. When the cells are confluent, PBS buffer (0.2 M NaCl, 2.7 mM KCl, 10 mM NaH2PO4, 1.8 mM K₂HPO₄) containing 0.25% trypsin and 0.02% EDTA can be added to detach the melanoma cells from a culture dish. The detached cell suspension can be 10-fold diluted with DMEM containing 10% FBS and then centrifuged at 250×g for 10 min at 4° C. After washing with DMEM twice, melanoma cells can be resuspended in DMEM containing 10% FBS, and their numbers counted by using a microscope to check the viability of the melanoma cells. The cells can be diluted to 2×105 cells/culture dish (100 mm in diameter) for passage and then incubated with 5% CO2 at 37° C. for 3 days.

B. Measurement of Tyrosinase Activity

L-Tyrosine oxidation by tyrosinase is spectrophotometrically determined.^(1,2) Forty microliters of 25 mM L-tyrosine, 80 μl of 67 mM sodium phosphate buffer (pH 6.8), and 40 μl of the same buffer with or without test sample are added to a 96-well plate, and then 40 μl of tyrosinase is mixed. The initial rate of dopachrome formation from the reaction mixture is determined as the increase of absorbance at wavelength 492 nm per min (ΔA 492/min) by using a Molecular Devices microplate reader. The Michaelis-Menten constant (K m) and maximal velocity (V max) of tyrosinase are determined by Lineweaver-Burk plot with various concentrations of L-tyrosine as a substrate.

C. Measurement of Promoter Activity of Murine Tyrosinase Gene

Murine melanoma B-16 cells (6×104) transfected with luciferase expression vector pGL2 containing the full-length promoter of murine tyrosinase is grown in DMEM containing 10% FBS with 5% CO2 at 37° C. for 24 h. After washing with PBS buffer, the cells are incubated with or without test sample for 6 h before harvesting. Luciferase activity in cell lysates is determined using a luciferase assay system (Promega) following the supplier's instructions. The light intensity is measured with a luminometer. Protein concentration is determined by the Bradford method with bovine serum albumin as a standard.

D. Statistics

Effects on tyrosinase by test samples are represented as inhibition % of {1−((sample ΔA 492/min)/(control ΔA 492/min))}×100 or control % of ((sample ΔA 492/min)/(control ΔA 492/min))×100. Data shall be collected as means±S.E. of three independent tests, and significant differences from the control is analyzed by the Student's t-test.

E. Procedures and Results

The effects of different chemical compounds are investigated using cell suspensions of uveal melanocytes and culture of murine melanoma cells, B16-F1. The cells are treated with different concentrations of specific medications and compounds described above for 72 h. Extracellular melanin is measured directly by collecting the tissue culture supernatants and taking absorbance at 490 nm. The melanin content can be measured using any of the previously reported methods (Tadokoro, T, et al, J. Invest. Dermatol. 124,1326-1332). Briefly, the cultured cells are solubilized in lysis buffer (1% Nonidet P-40; Calbiochem, San Diego, Calif., USA; in PBS containing a protease inhibitor cocktail; Roche, Indianapolis, Ind., USA) for 1 h on ice with occasional vortexing, and protein concentrations is measured with a bicinconinic acid kit (Pierce, Rockford, Ill., USA). Melanin pellets were dissolved by incubation in 1 N NaOH at 37° C. for 18 h. Aliquots of each sample were transferred to 96-well plates, quantitated by absorbance at 405 nm using an automatic microplate reader (Molecular Devices, Sunnyvale, Calif., USA), and calibrated against a standard curve generated using synthetic melanin (Sigma, St. Louis, Mo., USA).

Viability of cells is measured using standard tetrazoliumreduction assays that are based on redox potential of live cells. Treatment of cultured above mentioned melanocytes with designated medications for up to 6 d can reveal any cytotoxicity. (Terry L. Riss, Richard A. Moravec. ASSAY and Drug Development Technologies. February 2004, 2(1): 51-62. doi:10.1089/154065804322966315).

Results from tyrosinase activity, promoters activity, and cell viability of tyrosinase inhibitors and all the categories that has been described above, can be obtained in order to process the necessary steps to choose the best combination for the animal study.

EXAMPLE 2 Animal Study

Wild caught young adult female cynomolgus monkeys of any ages, weighing 2-3 kg, can be used for the study. Typically these animals have yellowish-orange iris color, with individual-to-individual differences in hue. The animals chosen shall have no detectable heterochromia between the eyes at baseline. The animals are euthanized after 25 or 38 weeks of treatment with a mixture of pentobarbital and ethanol, and the eyes are enucleated. The eyes are opened and the irides carefully excised, washed with PBS, and placed with the pigment epithelial side up in PBS on tissue paper. The pigment epithelium is carefully removed, rinsed in PBS, and wet weight determined. The tissue is kept frozen until analyzed for melanin.

The comparison of the treated and not treated eye of each individual animal is evaluated and documented to obtain the best combination possible for human study selection.

Prior to euthanasia, color photographs of the iris of both eyes of each animal (1:1 magnification) are taken at baseline, and at regular intervals thereafter through 6 weeks, using a calibrated digital color camera system. Photographs are of each eye with a calibration plate and an animal identifier, repeated every week. After color correction based on the calibration plates, the histograms of the iris portion of the photos are recorded, to be compared to reveal color shifts using peak detection in the hue and luminance histograms.

Determining the minimum shift required to qualify for a significant iris color change is done independent of the above, and can be done by the following method.

A set of 50 headshots of different people with different eye colors are obtained. 20 human subjects are shown each photo, immediately followed by the same photo manipulated using editing software to shift the peaks of the hue and luminance of the iris by a random amount. The subject is then asked if they notice what they would consider a significant color change in the eyes. The average of all responses is used to determine the threshold.

Analysis of the type and level of melanins in the stroma of treated and untreated control irides is achieved by a highly sensitive procedure based on alkaline hydrogen peroxide degradation, or reductive hydrolysis with hydriodic acid of the tissue, followed by HPLC quantitation of 2,3,5-pyrroletricarboxylic acid (PTCA), and isomeric aminohydroxyphenylalanines (AHPs), the specific structural markers of eumelanin and pheomelanin, respectively (GIUSEPPE PROTA1, et al., PIGMENT CELL RES 13: 147-150. 2000)

Tyrosinase activity and statistical analysis of the results is then performed as described above.

EXAMPLE 3 Bleaching Example 3A

A suspension with a combination of the following medication is used in this example.

-   -   1. Hydroquinone (Benzene-1,4-diol, Tyrosinase inhibitor)         Liposomes and/or micelle nanoparticles with Hydroquinone-loaded         multilamellar vesicles (MLVs) that are encapsulated in         poly(lactic-coglycolicacid) (PLGA) microparticles     -   2. Memantine (1-amino-3,5-dimethyl-adamantane, glutamate         receptor blocker)     -   3. Haginin A (an isoflav-3-ene, downregulator of mitf, tyr, and         Trp1)

The following four groups of animals are studied:

Group 1: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of saline.

Group 2: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of siRNA.

Group 3: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of botulinum toxin.

Group 4: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of botulinum toxin and siRNA.

The left eye will be the control for the drops in Group 1, and Group 1 (with saline injection) will be the control group for the injections. We then select the best result.

The change in the color of the treated right eye within 2 weeks of starting the treatment is observed. The decrease pigmentation appears as a lighter color eye compared to the untreated left eye. By the end of 3 months of treatment signaficant color change is observed. At this point the maintenance therapy can be initiated.

Example 3B

A suspension with a combination of the following medication is used in this example.

-   -   1. Oxyresveratrol (Tyrosinase inhibitor)     -   2. 4,4′-dihyldroxybiphenyl (downregulator of cAMP-dependent         protein kinase K and mitt)     -   3 H89 (Melanosome acidification)

The following four groups of animals are studied:

Group 1: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of saline.

Group 2: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of siRNA.

Group 3: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of botulinum toxin.

Group 4: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of botulinum toxin and siRNA.

The left eye will be the control for the drops in Group 1, and Group 1 (with saline injection) will be the control group for the injections. We then select the best result.

The change in the color of the treated right eye within 2 weeks of starting the treatment is observed. The decrease pigmentation appears as a lighter color eye compared to the untreated left eye. By the end of 3 months of treatment signaficant color change is observed. At this point the maintenance therapy can be initiated.

Example 3C

A suspension with a combination of the following medication is used in this example.

-   -   1. tetrahydroxyisoflavone (Suicide substrate)     -   2. prinomastat (matrix metalloproteinases inhibitor)     -   3. Naloxone (Opioid receptor antagonist)

The following four groups of animals are studied:

Group 1: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of saline.

Group 2: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of siRNA.

Group 3: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of botulinum toxin.

Group 4: one drop of the formulation above, twice a day (always in the right eye, with the left eye being the control), in conjunction with an injection of botulinum toxin and siRNA.

The left eye will be the control for the drops in Group 1, and Group 1 (with saline injection) will be the control group for the injections. We then select the best result.

The change in the color of the treated right eye within 2 weeks of starting the treatment is observed. The decrease pigmentation appears as a lighter color eye compared to the untreated left eye. By the end of 3 months of treatment maximum color change is observed. At this point the maintenance therapy can be initiated.

Example 3D

A thirty three year old female patient presents with heterochromia due to Horner's syndrome, complaining of differing eye colors. The darker eye is treated with eye drops containing 1% Memantine, 0.5% Thymoxamine, 10% Oxyresveratrol, and 2% Pilocarpine, one drop twice a day. In addition, injections of nanoparticle targeted botulinum toxin every three months are given using microneedles. Over time the darker eye lightens to resolve heterochromia. Maintenance drug therapy will continue, one drop twice a day, twice a week. The heterochromia does not redevelop.

Example 3E

A fifty seven year old male patient presents with glaucoma in one eye, complaining of disparity of eye color due to use of prostaglandin analog for treatment of glaucoma. The darker eye is treated with eye drops containing 2% Memantine, 1% Thymoxamine, 0.09% Bromfenac, and 20% Oxyresveratrol. Over time the darker eye lightens to resolve the disparity in eye color. The patient will have to continue the treatment as long as they are using prostaglandin analog.

Example 3F

A thirty year old female presents in the office with the request for lighter color eyes for cosmetic reasons. She mentions that all her life she wishes she had light colored eyes. A complete ophthalmological exam reveals no evidence of pathology or disease. She is informed of her options such as colored contact lenses and implants, and selects treatment using the following iris lightening technique. She is treated with eye drops containing 1% Memantine, 0.09% Bromfenac, 0.5% Thymoxamine, 5% H89, and 0.5% Naloxone, one drop, twice a day. In addition, injections of nanoparticle targeted botulinum toxin every three months are given using microneedles.

Example 3G

A 24 year old female with brown eyes presents in the office, explains as one of two identical twins she wishes to have her own separate identity, and as such desires lighter colored eyes. The ophthalmological examination revealed no evidence of pathology or disease. He is started on a formulation as in in Example 3F with similar results.

EXAMPLE 4 Coloring and Texturing

Trypan Blue biological dye (500 nm+wavelength absorption) is encapsulated in liposomes using procedure described above. The resulting liposomes are put in two batches, each batch targeting a different iris structure.

The first batch of liposomes is conjugated with a specific antibody to collagen type VI, using the referenced method in Targeting Agent Example described herein.⁵⁵ The second batch of liposomes is conjugated with Fibroblast Surface Protein (human) antibody^(63,64). The two batches are then mixed into a single mixture to be used.

A 50:50 mixture of Methyl Green (560 nm+wavelength absorption) and Fluorescein is encapsulated in liposomes using procedure explained in Example 1 above to be used to generate a glowing green color when exposed to UV, or a deeper green under normal light.

Example 4A

A 42 year old male with blue eyes presents in the office with the desire to change his appearance as part of the Witness Relocation Program. The ophthalmological examination revealed no evidence of pathology or disease. He is started on a melanocyte stimulatory formulation with resulting darkening of the eye to brown.

Example 4B

A 23 year old female with green eyes presents in the office, requesting Fluorescein glow in her eyes due to her profession as a hostess in a nightclub. The ophthalmological examination revealed no evidence of pathology or disease. She is treated with Fluorescein filled liposome formulation as described above. After treatment her iris began to glow under black light.

Example 4C

35 year old female with light green eyes, presents in the office requesting to change her eye colors to dark brown. Initial complete ophthalmologic examination reveals no evidence of ocular pathology. She is treated with topical solutions of:

-   1. Latanoprost commercially available ophthalmic solution 0.005% (50     μg/mL), one drop per day in each eye. -   2. Forskolin Commercially available eye drop 1%, also one drop once     a day in each eye. -   3. Ophthalmic suspension of (1-oleoyl-2-acetyl-glycerol 0.5%), one     drop twice a day until the desired color is achieved.

The color of the eye starts to darken by the first week of treatment and probably is not reversible. The treatment can be repeated in 3 months if further color darkening is desired.

Example 4D

43 year old male that has been treated with bleaching eye color treatment 2 years ago, presents to the office requesting to change the color of his eyes back to original dark brown.

Initial complete ophthalmologic examination reveals no evidence of ocular pathology. She is treated with topical solutions of:

-   1. Latanoprost commercially available ophthalmic solution 0.005% (50     μg/mL), one drop per day in each eye. -   2. Forskolin Commercially available eye drop 1%, also one drop once     a day in each eye. -   3. Ophthalmic suspension of (1-oleoyl-2-acetyl-glycerol 0.5%), one     drop twice a day until the desired color is achieved.

The color of the eye starts to darken by the first week of treatment and probably is not reversible. The treatment can be repeated in 3 months if further color darkening is desired.

CONCLUSION

The results from above examples show that use of the methods described herein effectively changes the amount of pigment melanin in the iris stroma, and/or introduce pigments or dyes, including fluorescent or metallic, thereby altering the appearance of the iris.

The subject matter of each of the references listed below is incorporated in this application by reference.

REFERENCES

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1. A method of lightening the color of the iris of a human subject, the method comprising administering to the iris of the human subject an amount of a composition comprising a tyrosinase inhibitor effective to lighten the color of the iris of the human subject.
 2. The method of claim 1, wherein the tyrosinase inhibitor is hydroquinone,
 3. The method of claim 1, wherein in the tyrosinase inhibitor is oxyresveratrol or tetrahydroxyisoflavone.
 4. The method of any one of claims 1-3, wherein the composition further comprises at least one melanogenesis inhibitor.
 5. The method of claim 4, wherein the melanogenesis inhibitor is selected from the group consisting of glutamate receptor blocker, an α-adrenergic blocker, a matrix metalloproteinases inhibitor, a Cox inhibitor, a cholinergic agonist, a downregulator of mitf, tyr & Trp1, an acidifier of melanosomes, an opioid receptor antagonist, a Pmel17 blocker, and a fibroblast growth factor inhibitor.
 6. The method of claim 5, wherein the glutamate receptor blocker is memantine, the α-adrenergic blocker is thymoxamine, the matrix metalloproteinases inhibitor is prinomastat, the Cox inhibitor is bromfenac, the cholinergic agonist is pilocarpine, the downregulator of mitf, tyr & Trp1 is Haginin A or 4,4′-dihyldroxybiphenyl, the acidifier of melanosomes is H89, the opioid receptor antagonist is naloxone, and the Pmel17 blocker is calmodulin inhibitors.
 7. The method of any one of claims 4-6, wherein the composition comprises hydroquinone, memantine and Haginin A.
 8. The method of any one of claims 4-6, wherein the composition comprises oxyresveratrol, 4,4′-dihyldroxybiphenyl and H89.
 9. The method of any one of claims 4-6, wherein the composition comprises tetrahydroxyisoflavone, prinomastat and naloxone.
 10. The method of any one of claims 1-9, wherein the composition is administered in conjunction with an injection of saline, siRNA, botulinum toxin, or a combination of botulinum toxin and siRNA.
 11. The method of any one of claims 1-10, wherein the composition is administered through a nanoparticle drug delivery system containing a targeting agent of iridial melanocytes.
 12. The method of claim 11, wherein the targeting agent is a composition of zinc.
 13. The method of claim 12, wherein the composition of zinc is zinc oxide.
 14. The method of any one of claims 1-13, wherein the composition is in the form of eye drops.
 15. The method of any one of claims 1-13, wherein the composition is administered through an ophthalmic drug delivery system selecting from the group consisting of salves, creams, emulsions and gels.
 16. The method of claim 14 or 15, wherein the composition is administered in the fornices under the eyelid.
 17. The method of any one of claims 1-13, wherein the composition is administered through an ophthalmic drug delivery system comprising a time-release coated insert.
 18. The method of claim 17, wherein the time-release coated insert is coated on at least one side.
 19. The method of any one of claims 1-18, wherein the subject is a healthy human.
 20. The method of any one of claims 1-18, wherein the subject is afflicted with glaucoma.
 21. A method of introducing pigments to the iris of a human subject, comprising administering to the iris an amount of at least one melanogenesis promoter, effective to introduce pigments to the iris of the human subject.
 22. The method of claim 21, wherein the iris of the human subject darkens after the introduction of pigments to the iris.
 23. The method of claim 22, wherein the at least one melanogenesis promoter is prostaglandin, forskolin, 1-oleoyl-2-acetylglycerol and 1,2-diacylglycerol, or lotus flower essential oil, or a combination thereof.
 24. A method of introducing pigments to the iris of a human subject, comprising administering to the iris an amount of a composition comprising a biological dye, effective to introduce pigment to the iris of the human subject.
 25. The method of claim 24, wherein the biological dye is a Trypan Blue or a Methyl Green biological dye.
 26. The method of claim 24 or 25, wherein the composition further comprises fluorescein.
 27. The method of claim 26, wherein the iris of the human subject changes color and/or glows.
 28. The method of any one of claims 21-27, wherein the composition is administered through a nanoparticle drug delivery system containing a targeting agent of iridial melanocytes.
 29. The method of claim 28, wherein the targeting agent is a composition of zinc.
 30. The method of claims 29, wherein the composition of zinc is zinc oxide.
 31. A nanoparticle composition for lightening pigmented tissues, comprising a targeting agent of melanocytes chemically bound to a pharmaceutical composition comprising a tyrosinase inhibitor.
 32. The nanoparticle composition of claim 31, wherein the targeting agent is a composition of zinc.
 33. The nanoparticle composition of claim 32, wherein the composition of zinc is zinc oxide.
 34. The nanoparticle composition of any one of claims 31-33, wherein the tyrosinase inhibitor is hydroquinone.
 35. The nanoparticle composition of any one of claims 31-34, wherein the pharmaceutical composition further comprises at least one melanogenesis inhibitor.
 36. The nanoparticle composition of any one of claims 31-35, wherein the pigmented tissues are skin or hair tissues.
 37. The nanoparticle composition of any one of claims 31-36, which is in the form of an injectable solution or a topically applied solution.
 38. A method for lightening pigmented tissues of a human subject, comprising administering the nanoparticle composition of any one of claims 31-37 to the human subject so as to lighten the pigmented tissues, wherein the targeting agent binds to cells of the pigmented tissues to permit the release of the pharmaceutical composition directly into the cells of the pigmented tissues without affecting non-pigmented cells.
 39. A nanoparticle composition for treating a pigmented tissue related disease, comprising a targeting agent of melanocytes chemically bound to a pharmaceutical composition comprising an active agent for the disease.
 40. The nanoparticle composition of claim 39, wherein the targeting agent is a zinc composition.
 41. The nanoparticle composition of claim 40, wherein the zinc composition is zinc oxide.
 42. The nanoparticle composition of any one of claims 38-40, wherein the disease is glaucoma or melanoma cancer.
 43. A method for treating a pigmented tissue related disease, comprising administering the nanoparticle composition of any one of claims 38-42 to the subject so as to treat the disease, wherein the targeting agent binds to cells of the diseased pigmented tissue to permit the release of the pharmaceutical composition directly into the cells of the diseased pigmented tissue without affecting non-pigmented cells.
 44. A method of depigmenting the iris melanocytes to lighten the color of the iris, comprising the steps of: Blocking the sympathetic and parasympathetic nerve supply to the melanocytes using botulinum toxin and memantine; Preventing tyrosine conversion to melanin by one of available tyrosinase inhibitors; Preventing Melanocyte-stimulating hormone activation (MSH) by using 2,5-Dimethyl-4-hydroxy-3(2H)-furanone (DMHF); Inhibiting the COX-2 enzyme using NSAIDS; Preventing melanogenesis by using a cholinergic agonist; Blocking Alpha 1-adrenergic receptors by using antagonist chemicals, or a combination thereof, and using the subject matter of any one of the preceding claims for delivering depigmenting compositions to melanocytes in the iris.
 45. The method of any one of claims 1-30, 38, 43 and 44, wherein the medication is transported into the anterior chamber of the eye by microneedles.
 46. The method of any one of claims 1-30, 38, 43 and 44, wherein the medication is transported into the anterior chamber of the eye by over-saturating the molecule carriers with the medication.
 47. The method of any one of claims 1-30, 38, 43 and 44, wherein the medication is transported inside the melanocytes via Folate receptors. 